DE4024143A1 - Insulated glass assembly - has flow channels at profiled distance holders between glass panes for heating or cooling medium to flow between them - Google Patents

Abstract

The glass insulation assembly, using two spaced glass panes held together by a profiled distance unit, has fixed connections to the distance holder or through it to give heat conductive components for a medium to flow through. ADVANTAGE - The assembly allows heat or a cooling medium to flow between the glass panes to reduce heat energy passing through the glass in summer or for cold outer air to pass through in winter.

Description

Subject of the invention

The invention relates to insulating glass consisting of at least two discs spaced apart and above Spacer profiles are interconnected.

State of the art

It is known to use insulating glass with or without a hermetic rim manufacture bund. It is also known to be insulating glass-like Constructions such as B. a window with on the inside small frame profiles attached to the main frame second or to "ventilate" the third pane. It is also known Double box windows with a ventilated space equip, over the warm air that z. B. on a blind forms suction.

Disadvantages of the prior art

A disadvantage of the ventilated constructions described is the high design effort for the double box window or additional frame constructions. Another disadvantage is the increased window width due to the elaborate frame constructions. Another disadvantage is the possibility of Dust entry between the panes over the frame profiles.

Object of the invention

The invention has therefore set itself the task of a problem to develop a solution in which the above disadvantages can be avoided. In addition, the object of the invention is a Manufacture insulating glass pane that is coolable or heatable to either in summer so the total energy passage of the glass reduce that the external heat input into the building reduces or to heat the window in winter to keep out the cold to prevent from the pane into the interior.  

The object of the invention is therefore the air between temperature between two panes of glass. This is supposed to a reduction in the cooling loads or heating loads of the building will. The energy is said to be at the thermally weakest point of the Ge building, the windows are led in and out to transmissions to compensate for gains or transmission losses. Hereby should reduce the cooling or air conditioning systems as well as the heating systems become possible. It is also said to be more comfortable can be achieved in the interior by the air and convection currents conditions are reduced by more balanced temperature conditions.

solution

The task is solved according to the characterizing part of the main claim.

advantages

The advantage of the solution according to the invention lies in the possibility to temper the insulating glass pane itself. The edge bond is used to either enter a gas in the air gap bring and vacuum this again or over the tempering of the edge bond itself a tempering of the panes and the to achieve trapped gas.

It is therefore intended to temper the disc by ent neither a cooled nor a heated gas or air over the Spacer profiles is sucked in or out - the distance In this case, holder profiles serve as air-guiding elements or it is without air exchange, only via the tem the spacers worked.

The advantage of tempering a window via the insulation Glazing yourself is part of the savings of a complex box double window or additional wing constructions. The window can be made compact and space-saving. Another advantage is the prevention of condensation in the glass bearing profile by heating the edge bond. Through the The edge bond is prevented from condensation protects and extends the life of the glass.  

Description of the figure drawings

Show it:

Fig. 1 shows the view of an insulating glass pane with the Randver bund and the air duct

Fig. 2 shows a perspective section through an edge bond with the air-guiding spacer profile

Fig. 3 is a view of an insulating glass pane with a temperature-controlled spacer and the convection circuits that form.

Fig. 4 shows the cross section through a temperature-controlled spacer with a flow-through tube integrated on the spacer profile.

Fig. 5 shows the parallel section through a corner of an insulating glass pane with a cooled spacer.

Fig. 6 shows the cross section through the edge composite of a 3-pane insulating glazing.

Fig. 1 is a view showing a double glazing profiles 10 with the spacers 11, 12, 13, 14. The spacer profiles 12 , 13 are designed to flow through, the air flowing through the profile 12 into the air gap of the insulating glazing 10 and flowing out through the spacer profile 13 . The air flows are symbolized by the arrows 18 , 19 and show that the air flows through openings in the spacer profiles evenly distributed over the entire width.

The spacer profiles 12 , 13 are connected to the supply air or exhaust air pipes 15 , 16 . The heated air in the exhaust pipe 15 is cooled in a heat exchanger 17 and returned through the supply air pipe 16 into the disc. It is a closed system, which makes it possible to operate the system with a special gas. The system can be used in reverse as a heater by the heat exchanger, the pipe coil 20 warms. The heat exchanger 17 with the coil 18 is to be understood more symbolically and could also be designed quite differently. There are e.g. B. air / water or air / air systems conceivable. The advantage of the presented, closed system lies in the fact that cleaned and dried air can be used ver, so that water vapor precipitation and pollution in the space between the panes are permanently avoided. The advantage of double glazing is therefore retained despite the air cooling or air heating. All pipe connections, like the insulating glass pane itself, are sealed in a water vapor diffusion-tight manner. As an additional security, a renewable container with desiccant 29 can be installed in the pipe system.

The system is operated either due to the buoyancy or sagging of the heated or cooled air in the disk, or by a pump 21 which is installed within the pipe system. In order to operate the system as a closed system, the pump must be installed within the pipe system. The power supply for the pump comes from outside contacts.

The term "double glazing" is in no way restrictive understand and does not only refer to constructions with one Water vapor diffusion-tight edge seal.

Fig. 2 shows the perspective section through the edge bond of the insulating glazing. The spacer profile 22 is connected to the glass panes 25 , 26 by means of an adhesive 23 , 24 . The resulting hollow space between the panes is lated by a sealant 27 versie. The spacer profile 22 is hollow and is ver applies as an air passage. The air flows through holes in the air gap of the insulating glazing, which is indicated by the arrows 28 .

FIG. 3 again shows the view of an insulating glass pane which, as in turn, has spacer profiles 31 , 32 , 33 , 34 through which the pane can be heated or cooled. In this example, a liquid medium flows through the profiles so that the spacer heats up or cools itself. Due to the heating or cooling of the spacer, a convection roller 35 , 36 is formed in the insulating glazing, which ensures temperature control in the entire pane. In the example shown, the vertical spacer profiles 31 , 34 are cooled, as a result of which the air at the spacers sinks downward. The cooled air warms up in the middle of the pane and rises. to cool off again at the spacers. While with insulating glass panes with very good insulation, each type of convection z. B. is prevented by heavy gases, convection is used here deliberately to temper the air gap. In contrast to normal insulating glazing, which has its best k-value with smaller distances between the panes (e.g. 12 mm pane spacing), a large pane spacing is advantageous in the invention in order to facilitate convection.

Fig. 4 shows the cross section through the edge composite with the spacer profile 36 , which is filled in a conventional manner with a Trockenmit tel 37 . A pipe 38 is saddled onto the spacer, through which a heat transfer medium (e.g. water or oil) is passed. The tube 38 is in thermally conductive connection with the spacer and is preferably together with the spacer as a single part, for. B. pressed from aluminum. The tube and the spacer are surrounded by a sealant 40 so that it also serves as thermal insulation for the tube. The tubes have heat conducting fins 39.1 to 39.5 to the space between the panes.

Fig. 5 shows the parallel section through a corner connection. In the present case, a conventional spacer profile 41 is combined with a spacer profile 42 according to the invention. The profiles 41 and 42 are connected to each other via an angular connector 43 . The profile 42, the tube is hitched 44 which communicates via a pipe 45 with a flow and return in connection. The flow and return is in turn with a heating or cooling system such. B. connected in the manner of a heat pump and / or via heat exchangers with cooling or heating. Forward 46 , 47 and return 47 , 48 are shown in Fig. 4. Of course, another type of supply and discharge would also be conceivable, e.g. B. in a circulating stream through all spacer profiles 31 to 34 with only one forward and return. The corner bracket 43 can be used by means of a pipe running diagonally across the corner for blowing and extracting heated or cooled air.

Fig. 6 shows a further embodiment of the invention. The cross-section through the edge bond of a 3-pane insulating glazing is shown, whereby between the outer panes 50 , 51 Lichtlenkpro file 53 , 52 are installed, which serve to regulate the solar radiation (Köster solar glass see e.g. DBZ 2/89 "Solartechnik" author: Köster). The disks 50 , 51 are held via spacer file 57 The spacer profiles 57 in turn have two chambers 58 , 59 , the chamber 58 receiving the desiccant, while the rectangular chamber 59 carries the coolant or heating medium. The chamber is rectangular in the present case. The inner disk 52 is connected to the middle disk 51 via the spacer 60 . The spacer is made wider to enable a better convection in the air gap 61 . The spacer profile 60 is - to introduce a further embodiment of the invention - designed only as a simple hollow profile. In the cavity of the spacer profile 60 capillary tubes 62 , 63 , 64 are inserted through which a liquid medium flows. This type of training has the advantage that special connections are unnecessary. The pipes are led out of the edge composite and coupled into a closed circuit outside the same. The advantage of this type of education is also that ge can be used with angled spacer profiles, ie the capillary tubes (diameter approx. 2 to 10 mm) are inserted into the spacer profiles, in a further step the spacer profiles are angled according to the pane sizes and into a frame element shaped.

Another, not shown embodiment of the innovation exists in the capillary tubes outside the spacer profile in the Insert edge seal and seal.

The three-pane glazing has the advantage of being able to intercept and dissipate the heat radiation from the outer insulating glazing 50 , 51 . This pane structure is particularly favorable if, for example, the second pane 51 is tinted and heats up due to the coloring. The heat does not radiate into the interior, but is dissipated by cooling the air gap 61 . The three-pane glazing also lends itself to the renovation of windows by subsequently placing a third pane on the interior side using the spacers according to the invention.

It is particularly advantageous to design the light-directing profiles 52 to 55 to be heat-conductive - that is, for. B. also steel or aluminum - and heat conductive to connect with the spacer.

Claims (10)

1. Insulating glass consisting of at least two panes which are arranged at a distance from one another and are connected to one another via spacer profiles, characterized in that the spacers ( 12 , 13 , 31 , 34 , 36 , 41 , 42 , 22 , 57 , 60 ) or parts ( 38 , 45 , 43 , 62 , 63 , 64 ) in fixed and heat-conducting connection with the spacers are designed as flow-through components. 2. Insulating glass according to claim 1, characterized in that the stand-up profiles ( 13, 18, 22 ) are formed from a gas (air) through which they can flow and have openings for the air gap ( Fig. 2). 3. Insulating glass according to claim 2, characterized in that the spacer profiles ( 12 , 13 , 22 ) to a closed air circuit are closed, with opposite spacer profiles ( 12 , 13 ) gas in or out in the air gap and the gas in a heat exchanger ( 17 ) is heatable or coolable. ( Fig. 1) 4. Insulating glass according to claim 1, characterized in that the stand-up profiles ( 31 , 34 , 36 ) are designed as liquid-flowable tubes. ( Fig. 3, 4) 5. Insulating glass according to claim 4, characterized in that the Ab standhalterprofile ( 36 , 57 ) are designed as two-chamber hollow profiles, wherein a chamber can be flowed through by a liquid medium. 6. Insulating glass according to claim 1, characterized in that in the spacer profile ( 60 ) or in the edge bond outside the stand-off profile from 60 liquid-flowable tubes ( 62 , 63 , 64 ) are inserted. 7. insulating glass according to claim 1, 4, 5, 6, characterized in that the liquid-flowable tubes ( 31, 34, 36, 37, 62, 63, 64 ) are connected to a closed circuit and that a heat exchanger is installed within the closed circuit is. 8. insulating glass according to claim 1, 2 or 3, characterized in that outside the insulating glass, however, inside the closed Air circuit a container with desiccant is arranged. 9. Insulating glass according to claim 1, characterized in that the corner brackets ( 43 ) have devices for blowing in or escaping gas (air). 10. Plant according to one or more of the preceding claims, characterized in that the spacers ( 36 ) on the side facing the window interior have lamellae ( 39.1 to 39.5 ).